Refractories and use thereof

ABSTRACT

A refractory has the form of a dry, mineral batch of fire-resistant mineral materials combined in such a way that refractories which are long-term resistant to fayalite-containing slags, sulfidic melts (mattes), sulfates and non-ferrous metal melts and are used for refractory linings in industrial non-ferrous metal melting furnaces can be manufactured. The refractory at least contains:—at least one coarse-grained magnesia raw material as the main component;—magnesia (MgO) meal;—at least one fire-resistant reagent which, during the melting process, acts (in situ) in a reducing manner on non-ferrous metal oxide melts and/or non-ferrous metal iron oxide melts and converts same into non-ferrous metal melts.

The invention relates to refractory products, particularly in accordance with DIN ISO/R 836, DIN 51060, in the form of dry, mineral batches or mixtures on the basis of at least one magnesia raw material as a coarse-grained main component, suitable for the production of refractory products for the lining of industrial non-ferrous metal smelting furnaces, as well as in the form of non-molded or molded refractory products produced from the batches, for example in the form of molded bricks, which, when used in industrial non-ferrous metal smelting furnaces, are highly resistant to attack by fayalite slags (iron silicate slags), sulfidic slags (mattes), and sulfates, and are resistant to non-ferrous metal melts, particularly copper melt, over the long term. The invention furthermore relates to the use of non-molded or molded refractory products produced from the batches in an industrial non-ferrous metal smelting furnace, particularly in the region of a furnace zone operated in an oxidizing manner, preferably in the slag melt zone of an industrial non-ferrous metal smelting furnace.

Within the scope of the invention, the term “refractory product” is used as a general term for a refractory batch and for refractory products that are produced from a batch, for example using a liquid binder and/or water, for example by means of molding and/or pressing.

The term “meal” or “powder” is used, within the scope of the invention, to refer to grainings that comprise usual grain size distributions, for example a Gaussian grain size distribution, and the maximal grain size of which lies below 1.0, particularly below 0.5 mm, for example, at 95 wt.-%, determined as a screen passage value d₉₅, for example.

Coarse-grained means that the granulate graining comprises a usual grain size distribution, for example a Gaussian grain size distribution, for example at 95 wt.-%, particularly ≧0.5, preferably ≧1.0 mm, also determined as a d₉₅ value, for example.

Coarse-grained component or main component means that the coarse graining can form a supporting framework with reciprocally supporting grains in a product produced from a batch.

Non-ferrous metals, also called non-ferrous metals, such as copper, lead, zinc, nickel or the like, are melted, for example from sulfidic ores, in different vessels, on a large technical scale (for example Pierce-Smith converters, QSL reactors or shaft furnaces). The smelting processes are carried out in zones that are operated both in reducing and in oxidizing manner, i.e. with both reducing and oxidizing smelting sequences, in an industrial non-ferrous metal smelting furnace.

The so-called the running time of the furnaces depends, among other things, on the type of refractory brickwork—also called lining—which on the one hand protects the metal mantle of the furnace from the effects of high temperatures of the melted material, flames, and atmosphere, for one thing, and lowers heat losses, on the other hand.

Sulfidic non-ferrous metal ores, for example copper ores, are mainly compounds of metal, for example copper, iron, and sulfur. The compositions of the ores are greatly dependent on the respective deposits.

The refining process that begins with these ores starts with pretreatment and subsequent smelting of the ores. Sulfidic melts having high iron contents as well as a sulfur-containing atmosphere are characteristic for this process.

In the subsequent step, these sulfidic melts are converted to a metal oxide melt, for example a sulfidic copper melt is converted to what is called blister copper. For this purpose, the iron component in the initially sulfidic melt (for example Cu—Fe—S) is first lowered to below 1% by way of a slag formation process. For this purpose, while adding quartz sand (SiO₂), the iron is bound in a fayalite slag (Fe₂SiO₄) that forms, and removed from the process. The remaining melt, on the basis of Me-S, for example Cu—S (generally Cu₂S), is oxidized by blowing air into the melt, for example converted to blister copper. Essential corrosive media in this process are not only the sulfidic melt (Me-Fe—S, for example Cu—Fe—S with a decreasing Fe content during the course of the process) but also the formed fayalite slag (Fe₂SiO₄), the high concentration of sulfur in the atmosphere, and the proportions of copper and copper oxide that form at the end of the process.

In the last step of the pyrometallurgical route, the oxidized Me melt is processed further to produce pure metal, for example the blister copper is processed to produce anode copper. In this process, the melt is purified further, with removal of the remaining sulfur and iron. Essentially, the process is determined by means of liquid metal, for example copper, and the resulting slag phases on the basis of Me-Fe—O, which represent the corrosion substances.

In addition, great erosive wear occurs in all the aforementioned processes, due to partly turbulent flow conditions.

The furnace brickwork of an industrial non-ferrous metal smelting furnace is generally exposed to great temperature change stresses and great mechanical and chemical stresses. The temperature change stresses result from the batch method of operation and from blowing in cold process substances. Mechanical stresses are brought about, for example, by means of rotational movements of the furnace. Chemically, the masonry is subjected to stress caused by process slags and metal melts and by volatile compounds of the furnace atmosphere.

Smelting furnaces are classified, in terms of lining technology, in different zones, because the zones are subjected to different stress during operation. In the case of the QSL reactor, for example, a distinction is made between the reaction region, the oxidation region, and the related nozzle regions. Wear of the refractory material is primarily caused by chemical corrosion and by slag attack and other process substances, as well as spalling of infiltrated layers caused by temperature change stresses.

While according to the state of the art, a large proportion of the inner lining of a smelting furnace is generally lined with normal MgO bricks or MgO—Cr₂O₃ bricks, the slag zones and, above all, the nozzle zones must be reinforced with very high-quality, highly fired, so-called directly bound, magnesia chromium bricks.

Such refractory linings are found in all types of non-ferrous metal smelting furnaces, independent of their design.

By their nature, the known fired refractory products have an open porosity, which lies approximately in the range between 13 and 20 vol.-%. During the process, process substances such as slags, melts or gases can infiltrate into these open pores and decompose the structure of the brick by means of chemical reactions and/or lead to completely changed thermomechanical properties of the structure in comparison with the original properties of the refractory material. Alternating chemical attacks as well as alternating thermal and thermomechanical stresses lead to accelerated wear and structure weakening, particularly after foreign substance infiltration and corrosion of the refractory product components or of the brick components.

Fayalitic slags are formed during the production of non-ferrous metals from sulfidic ores, for example during the production of copper from copper pyrite (CuFeS₂). Copper pyrite is roasted, resulting in what is called copper matte that contains copper sulfite (Cu₂S) and iron compounds, for example FeS and Fe₂O₃. The copper matte is processed further to produce raw copper, wherein molten copper matte is treated in a converter, with air being supplied and SiO₂ being added, for example in the form of quartz. In this process, a fayalitic slag is formed, which primarily contains the mineral fayalite (2FeO.SiO₂) and raw copper oxide (Cu₂O).

As has already been mentioned, converters for the production of raw copper, for example a Pierce-Smith converter, are primarily lined with fired magnesia chromite bricks at this time (for example DE 14 71 231 A1). However, in this regard, these refractory products only insufficiently withstand attack by sulfates, which result from oxidation of the sulfides, for example in the form of magnesium sulfate. Magnesia chromite bricks furthermore have only limited or insufficient high-temperature anti-wetting properties for non-ferrous metal melts, and they comprise insufficient penetration resistance to hot non-ferrous metal melts.

Magnesia chromite bricks are also used in smelting units for the production of other non-ferrous metals or non-ferrous metals such as Ni, Pb, Sn, Zn, and result in similar problems there.

Refractory masonry of an industrial non-ferrous metal smelting furnace is known from DE 103 94 173 A1, in which furnace non-ferrous metals such as copper, lead, zinc, nickel or the like are melted at temperatures above 700° C. in an oxidizing zone of the furnace, wherein the masonry composed of non-fired bricks composed of refractory material such as MgO or refractory material in which MgO is at least partially replaced with spinel and/or corundum and/or bauxite and/or andalusite and/or mullite and/or flint clay and/or chamotte and/or zirconium oxide and/or zirconium silicate. The bricks have carbon in the form of graphite and of a coke structure formed by a binder that contains carbon, at least on the fire-side or hot-side surface region of the masonry. Within the chemical/physical milieu of the refractory material indicated in this prior art, the carbon is supposed to reduce slag infiltration as the result of a thin, sealing infiltration zone that forms in situ, wherein first reaction products are formed in the brick from the structural components of the brick, obviously when oxygen enters; these products clog pore channels of the brick in situ, so that at least continued entry of oxygen into the structure of the brick components is reduced and thereby a further reaction of the oxygen with carbon is prevented.

A refractory product according to ISO R/836, DIN 51060 for refractory masonry in industrial non-ferrous metal smelting furnaces is known from DE 10 2012 015 026 A1, in the form of a non-molded or molded batch, for example in the form of molded bricks, wherein the refractory product is supposed to be resistant to a high degree, in situ, to attack of fayalitic slags (iron silicate slags) and sulfates and resistant to molten non-ferrous metals, particularly to copper melt. A good anti-wetting property against non-ferrous metal melts, particularly against copper melt, improved penetration resistance against fayalitic slags, and improved resistance against sulfate attack at use temperatures are achieved by means of the use of an olivine raw material as the main component of the refractory product, as well as magnesia meal and silicon carbide meal. A refractory batch that contains the aforementioned substances can be mixed with a liquid binder in the form of silica sol.

Use of olivine raw materials containing forsterite contents (MgSiO₄) of at least 70 wt.-% guarantee great corrosion resistance and infiltration resistance against the large amounts of fayalitic slag (FeSiO₄). If fayalite slag comes into contact with the refractory material of the structure of the refractory product, the liquidus temperature of the slag increases. The slag “freezes up” onto the refractory material, and therefore further wear reactions do not occur.

Furthermore, the olivine raw material or the forsterite in the olivine raw material comprises poor wettability with regard to non-ferrous metal melts, particularly copper melt, and also very good sulfur corrosion resistance.

In the known refractory products, magnesia can react to form magnesium sulfate, with severe corrosion rates, and this can cause structure weakening. Furthermore, secondary silicate phases that contain calcium, such as dicalcium silicate, merwinite, and monticellite in the magnesia can weaken the structure.

The refractory products or products described in DE 103 94 173 A1 and DE 10 2012 015 026 A1 have proven themselves in superior manner in comparison with the magnesia chromite bricks used previously.

In the case of the two refractory products on the basis of MgO plus graphite (DE 103 94 173 A1) or olivine raw materials having at least 70 wt.-% forsterite contents (DE 10 2012 015 026 A1), as well as in the case of the magnesia chromite bricks, however, the inviscid Me oxides, for example the inviscid copper oxides, but in part, also the inviscid iron oxides, particularly the inviscid Me-Fe oxides, for example the copper iron oxides of the process particularly wet the basic refractory material very greatly. This results in high infiltration potential of these inviscid melts, with the result that the infiltrated structure is weakened. Although the problem is known, it has not been satisfactorily solved until now.

It is the object of the invention to create refractory products on the basis of magnesia raw materials as a coarse-grained main component, which products are significantly more resistant to attack by inviscid non-ferrous metal oxides, particularly by inviscid copper oxides, and/or inviscid non-ferrous metal iron oxides, particularly inviscid copper iron oxides during the smelting process. In this regard, however, the refractory products are also supposed to comprise the good anti-wetting properties against pure non-ferrous metal melt, particularly against pure copper melt, to withstand the penetration of fayalitic slags well, and to guarantee resistance to sulfate attack at working temperatures.

This object is accomplished by means of a refractory product in the form of a refractory batch on the basis of coarse-grained granulate composed of at least one magnesia raw material, particularly one that is low in iron, having high MgO contents, for example of at least 90 wt.-% MgO as the main component, as well as containing magnesia meal, particularly high-quality and low-iron, sulfur-resistant magnesia meal, and at least one refractory reagent that has a reducing effect during the smelting process, suitable for reduction of molten inviscid non-ferrous metal oxides and/or molten inviscid non-ferrous metal iron oxides, for example in the form of fine-particle carbon, for example in the form of graphite and/or of a coke structure formed from binder for refractory products that contains carbon, and/or carbon black and/or coke and/or anthracite. In the following, this batch with these ingredients will also be referred to as a basic batch.

High-quality is supposed to mean that the secondary phases that are usually present, such as dicalcium silicate, merwinite, monticellite, etc. are present at less than 2.5 wt.-%, for example. Sulfur-resistant is supposed to mean that the MgO meal is supposed to be low in such silicate secondary phases, because these are usually attacked first by sulfur compounds. For example, the MgO content of the magnesia is supposed to be ≧97 wt.-%. The low-iron magnesia raw material and the low-iron magnesia meal are supposed to have less than 10 wt.-% iron (III) oxide, for example.

Preferably, the batch can additionally have a fine-particle, powder-form silicic acid.

In addition, within the scope of the invention, is generally supposed to mean that a respective admixture and/or a respective additive is added up in the respectively indicated amounts to the mixture of magnesia raw material, magnesia meal, and reagent (basic batch), which mixture is mixed to come to 100 wt.-%.

The batch can preferably additionally also contain known antioxidants for refractory products.

Fine-particle is preferably supposed to mean that the silicic acid is present in the form of microsilica and/or pyrogenic silicic acid and/or precipitated silicic acid.

The invention therefore provides for the use of at least one fine-particle mineral refractory reagent that has a reducing effect on the aforementioned inviscid melts, within the structure of a refractory lining product for non-ferrous metal smelting furnaces according to the invention, produced from a batch according to the invention, wherein the reagent has the property of reducing inviscid non-ferrous metal oxide melt and/or non-ferrous metal iron oxide melt that comes into contact in situ, i.e. in a non-ferrous metal smelting furnace, with the structure during the smelting process, to form corresponding pure non-ferrous metal melts, so that then, the anti-wetting properties of the other structure components of the refractory lining product and, in the case of the use of graphite, furthermore also the anti-wetting properties of the graphite can act on the non-ferrous metal melts. This results in a high degree of corrosion resistance and infiltration resistance of the lining products according to the invention.

Preferably, fine-particle carbon, for example carbon in meal form, particularly in the form of graphite and/or a carbon that results from a binder that contains carbon, by means of temperature action, for example of a coke framework of the product structure, is provided as a reducing reagent. Carbon black and/or anthracite and/or coke, for example, can be used as alternative or additional further fine-particle reducing reagents.

The reducing reagents are preferably contained in the refractory basic batch or in the refractory lining product in amounts between 1 and 20, particularly between 5 and 15 wt.-% with reference to the basic batch components, for example at a fineness below 1000 μm.

The reducing reagent is contained in a batch according to the invention in a mixture with other components, particularly homogeneously distributed. In a refractory lining material produced from a batch according to the invention, particularly in a solidified shaped molded body, for example in a refractory molded brick, the reducing reagent is also present in the structure of the body, particularly also homogeneously.

Non-molded refractory products produced from a batch according to the invention are batched up with water, for example, and/or at least one known binder for refractory products, for example a liquid binder that contains carbon, and introduced into a non-ferrous metal smelting furnace as a refractory lining, wherein subsequent drying and/or tempering, for example, brings about solidification of the freshly batched-up mass. However, drying or tempering can also take place during start up or initial heating of the industrial non-ferrous metal smelting furnace in situ.

Molded refractory products, such as bricks, for example, produced from a batch that contains water and/or at least one known binder for refractory products, for example a liquid binder that contains carbon, are generally dried and/or tempered and subsequently used to line an industrial non-ferrous metal smelting furnace. However, the products produced from the batch can also be fired ceramically and subsequently used as intended.

A refractory batch according to the invention is mainly formed from the basic batch composed of a dry material mixture of coarse-grained magnesia, magnesia meal, and reducing reagent, for example graphite as a reducing reagent. Furthermore, it is practical if a dry batch according to the invention can additionally contain up to 4, particularly up to 2.5 wt.-% of antioxidants usually used for refractory products, and/or other additives and/or admixtures usually used for refractory products, wherein, however, the amount ratio of the components coarse-grained MgO, MgO meal, and reducing reagent, for example graphite, of the basic batch is supposed to be maintained.

It is surprising that the reducing reagent, such as the graphite and, if applicable, also the carbon that is derived from the binder that contains carbon, by means of tempering, or the other named carbons is/are only insignificantly consumed by means of oxidation under oxidation conditions in situ, i.e. during smelting operation of an industrial non-ferrous metal smelting furnace. Antioxidants contribute to this—if present—for one thing, as is known, but for another thing the structural milieu of a lining according to the invention obviously also contributes significantly to this, but this cannot be explained as yet. In any case, the carbon surprisingly acts in reducing manner in the structure on wetting and penetrating inviscid non-ferrous metal oxide melts and non-ferrous metal iron oxide melts of the smelting process, so that pure non-ferrous metal melt is produced from the oxides, on which the anti-wetting property of the carbon present in the structure, particularly of the graphite, then acts, and thereby further penetration of inviscid oxide melt into the structure is at least hindered.

The use of high-quality magnesia raw materials containing MgO contents (MgO), for example, of at least 90 wt.-%, guarantee great corrosion resistance and infiltration resistance to the large amounts of fayalitic slag (FeSiO₄). If a fayalite slag comes into contact with the refractory material of the structure of the refractory product, absorption of magnesia from the refractory material occurs (corrosion), but thereby the MgO content of the slag increases, and therefore the liquidus temperature of the slag also increases, and the solution potential of the slag with regard to the refractory material clearly decreases. The slag “freezes up” on the refractory material, and therefore further wear reactions do not occur.

In this regard, the components of a batch according to the invention or of a refractory product produced from a batch according to the invention mainly act as follows:

MgO Coarse-Grained:

Because of the great corrosion resistance to fayalite slag and to non-ferrous metal iron oxide melts, great resistance to corrosion is guaranteed. Furthermore, the highly refractory magnesium oxide guarantees great refractoriness.

MgO Meal:

Method of effect the same as MgO coarse-grained. Furthermore formation of forsterite with SiO₂ added to the bath and/or SiO₂ from slag components; resulting from this, reduction in porosity and occurrence of forsterite properties such as slag stiffening effect and anti-wetting effect against non-ferrous metal melt.

Reducing Reagent:

Reduction of inviscid non-ferrous metal oxide melts or non-ferrous metal iron oxide melts of the smelting process that come in contact with the structure.

Forsterite Formed In Situ:

Non-wetting effect against non-ferrous metal melt and non-ferrous metal oxide melt.

The magnesia raw material (available on the market in corresponding qualities) is used, according to the invention, as a coarse-grain granulate—as it is called in the field—and is supposed to preferably have 100 wt.-%, if possible, but at least 90 wt.-% of the mineral periclase, according to the invention. The rest can be other known contaminants of the raw material, such as monticellite and/or merwinite and/or belite.

The grain size of the magnesia raw material granulate that is used lies in the medium-grain and coarse-grain range, for example by at least 95 wt.-%, for example between 0.1 and 8, particularly between 1 and 8 mm, wherein the granulate can have a Gaussian grain size distribution, for example, or can be formed from grain fractions having irregular grain size distributions.

The magnesia raw material is particularly used in amounts from 30 to 74, particularly from 40 to 65 wt.-% in the basic batch mixture according to the invention.

The fine-particle magnesia is used in the form of a meal or powder having grain sizes, as determined by means of screening, for example, of 95 wt.-%≦1 mm (d₉₅≦1 mm), for example.

Fused magnesia and/or sintered magnesia and/or synthetic dead-burned or caustic magnesia, for example, is used as the magnesia.

The terms “meal” and “powder” are understood to be the same terms having the same meaning within the scope of the invention, as they are also known in the field. The terms are generally understood to mean dry, loose bulk granular materials composed of solid particles having a particle size ≦1 mm at 95 wt.-% (d₉₅).

The MgO content of the magnesia meal should preferably amount to >90 wt.-%, particularly >95 wt.-%. The rest is usual contaminants such as silicates and/or iron oxide.

The MgO meals have a Gaussian grain size distribution, for example.

The MgO meal is used in the dry basic batch mixture in amounts of 25 to 50, particularly of 35 to 45 wt.-%.

The batch can additionally also contain silicon carbide (SiC).

Silicon carbide is available on the market as a synthetic product having a high degree of purity and in different grain sizes and grain size distributions, and is used, according to the invention, in powder form or meal form, for example with grain sizes ≦1 mm at 95 wt.-% (d₉₅). The grain size distribution preferably corresponds to a Gaussian grain size distribution.

The SiC powder is used at a purity of >90 wt.-%, particularly >94 wt.-% of SiC. The additional added amount used amounts up to 15, particularly up to 10 wt.-%.

The additional fine-particle dry silicic acid is a silicic acid, for example, that reacts with the MgO of the magnesia meal in an aqueous milieu, with the formation of magnesium silicate hydrate phases, and forms magnesium silicate hydrate gel and/or magnesium silicate hydrate crystallites and/or magnesium silicate hydrate crystals. The SiO₂ content of the fine-particle dry silicic acid preferably lies above 90 wt.-%, particularly above 94 wt.-%. It has surprisingly been shown that dry fine-particle silicic acid forms MSH phases with the MgO of the magnesia more quickly when water enters into the batch according to the invention, and hardens more quickly, and produces higher cold pressure strength values.

The silicic acid must be selected to have such fine particles that a reaction between the MgO of the magnesia particles and particles of the silicic acid occurs in a fresh batch mass that is formed by means of adding water to a dry batch according to the invention and mixing, and magnesium silicate hydrate phases—also called MSH phases hereinafter—form, for example as a gel and/or crystallites and/or crystals, which bring about solidification of the mass that contains water, in the manner of hydraulic setting. Preferably, the batch is put together in such a manner, for this purpose, that a pH value above 7, particularly above 10 occurs in the aqueous milieu, in other words after water is added to the batch according to the invention.

Accordingly, crystalline quartz meals having a fineness of the quartz particles below 500, particularly below 200 μm, are suitable for the reaction to form MSH phases.

Furthermore, the following are particularly suitable for the invention as dry, fine-particle silicic acids:

Silica Dust

Silica dust is a very fine, non-crystalline, amorphous SiO₂ powder, which is formed in an electric arc furnace as a byproduct in the production of elemental silicon or of silicon alloys. It is offered for sale on the market under the trade names silica dust or micro-silica, for example, and generally has more than 85 wt.-% SiO₂. The particle size of the silica dust—also called silica fume—generally lies below 1 mm. The English term is “silica fume.”

Pyrogenic Silicic Acid

Pyrogenic silicic acids are very pure SiO₂ powders having SiO₂ contents up to 99 wt.-% and generally particle sizes between 50 and 50 nm, for example, and a high specific surface area between 50 and 600 m²/g, for example. These silicic acids are produced by means of flame hydrolysis. Pyrogenic silicic acid is offered for sale on the market under the trade name Aerosil, for example. The English term is “fumed silica.”

Precipitated Silicic Acid

In the production of precipitated silicic acid using the wet path, one proceeds from alkali silicate solutions from which very pure amorphous silicic acids are precipitated by means of the addition of acid (86-88 wt.-% SiO₂; 10-12 wt.-% water). The particle size lies between 1 and 200 μm, and the specific surface area between 10 and 500 m²/g. Precipitated silicic acids are sold under the trade names “Sipernat” or “Ultrasil,” for example. In spite of the water content, these silicic acids are not liquid but rather dry and powdery.

Within the scope of the invention, at least one of the aforementioned silicic acids is used according to a particular embodiment. It is practical if the silicic acids are selected with regard to their ability to react with the MgO of the magnesia meal, and if it is ensured that the silicic acid reacts with MgO as completely as possible when hardening.

The fine-particle dry silicic acid is added to the dry batch mixture at up to 10, particularly from 0.5 to 6 wt.-%.

According to one embodiment, according to the invention preferably only water is added to the dry basic batches according to the invention as described above, which are calculated to 100 wt.-%, for production of refractory products according to the invention.

Preferably, therefore, the following dry basic batches are composed in wt.-%:

Coarse-grained magnesia: 30 to 74, particularly 40 to 60, Magnesia meal: 25 to 50, particularly 35 to 45, Reducing reaction 1 to 20, particularly 5 to 15 substance, particularly carbon, particularly graphite:

The following components can be additionally added to this mixture of the basic batch, preferably in the following amounts in wt.-%.

Fine-particle silicic 0 to 10, particularly 0.5 to 6 acid: Fine-particle SiC: 0 to 15, particularly 0 to 10 Antioxidants: 0 to 4, particularly 0.5 to 2.5 Coarse-grained 0 to 4, particularly 0.1 to 3.5 refractory material granulate: Fine-particle 0 to 4, particularly 0.1 to 3.5 refractory material: Additive for refractory 0 to 2, particularly 0.1 to 1.5 products: Binder for refractory 0 to 10, particularly 0.1 to 6 products:

Preferably, the silicic acid is at least one of the aforementioned amorphous silicic acids.

The amounts of the reaction partners MgO meal and SiO₂ in batches according to the invention are selected in such a manner that when water is added from 1 to 10, particularly from 2.5 to 6 wt.-% with reference to the dry substance of the batch, during a time period between 6 and 120, particularly between 8 and 12 hours, in a temperature range from 50 to 200, particularly from 100 to 150° C., cold pressure strengths from 40 to 160, particularly from 60 to 150 MPa can be guaranteed.

Preferably it is provided, according to the invention, that the MgO of the magnesia meal that is capable of reaction is present, in terms of amount, predominantly with reference to the fine-particle silicic acid that is capable of reaction. From this, the result is supposed to be achieved that after water is added, MgO-rich MSH phases are formed, which can form forsterite (2 MgO.SiO₂) under the effect of high temperatures up to 1350° C., for example, which increases the forsterite proportion.

According to the invention, predominant mass ratios of MgO to SiO₂ up to 500:1 are practical. In particular, the ratio lies between 1.2:1 and 100:1, preferably between 1.34:1 and 50:1, very particularly preferably between 1.34:1 and 35:1.

Refractory products according to the invention are produced from dry batches according to the invention, after water is added, wherein a mixture with amounts of water, with reference to the mass of the dry batch, amounts to 1 to 10 wt.-%, preferably 2.5 to 6.0 wt.-%.

The so-called fresh masses that contain water, for example for monolithic linings, with water contents between 1 and 5, particularly between 1.5 and 3 wt.-%, are pressed, according to the invention, using usual pressing methods, to form molded brick blanks. The molded bricks are allowed to harden and dry, according to the invention, in the temperature range between 15 and 200, preferably between 50 and 200, particularly between 100 and 150° C., with MSH phases being formed. After hardening, the bricks demonstrate relatively great strength and can be handled, so that a refractory lining can be built from them. According to the invention, the bricks have cold pressure strength values between 40 and 100, for example, particularly between 60 and 80 MPa.

It lies within the scope of the invention to ceramically fire the molded and, if applicable, tempered and dried bricks, so that sintered products, for example, out of forsterite, are formed from MSH phases, for example, and sintering bridges out of forsterite are formed, for example, between the olivine grains or olivine particles and/or MgO meal particles and/or, if applicable, SiO₂ particles. Ceramic firing is preferably carried out in the temperature range from 400 to 1400, particularly from 600 to 1200° C., and over a time period from 1 to 24, particularly from 4 to 12 hours, wherein it is advantageous to conduct firing in a reducing atmosphere.

It is sufficient to add from 1 to 5, particularly from 1.5 to 3 wt.-% water to a batch according to the invention for pressing of bricks, particularly for the formation of MSH phases.

It lies within the scope of the invention to additionally provide known plasticizers in the batch or to add them to the mix that contains water, in order to increase the ductility of the mix. Such plasticizers are known to a person skilled in the art. They are generally added in amounts from 0.01 to 2, particularly from 0.1 to 1.5 wt.-%.

With higher water contents, for example from 4 to 10 wt.-%, particularly from 4 to 6 wt.-%, ductile casting masses or ramming masses are produced, according to the invention, from the dry batches according to the invention, and refractory monolithic pre-molded prefabricated parts are produced from them by means of shaping in molds. In this regard, solidification in the case of MSH phase formation takes place at room temperatures, for example, and drying takes place with a corresponding elevated temperature treatment. In this regard, the strength development of the molded mass corresponds to that of molded and tempered brick structures that form a coke framework.

It is practical if a product according to the invention is produced in that a homogeneous mix with a predetermined plastic or ductile or flow-capable processability is produced from a batch having at least the dry substances coarse-grained magnesia, magnesia meal, and reducing reagent, for example carbon in the form of carbon black and/or graphite and/or anthracite and/or coke, as well as, if applicable, silicic acid and/or SiC and/or antioxidants and/or dry, particularly powder-form synthetic resin binder, and/or flow agents and water and/or a liquid binder for refractory products, using suitable mixers. This ductile or flow-capable mass of the mix can be used on site for lining smelting converters. As has already been described, however, monolithically molded prefabricated parts or pressed bricks can also be produced from the mix; the latter can be used for lining smelting converters, for example, either unfired or ceramically fired.

The invention therefore also relates to a dry batch composed exclusively or mainly, for example, i.e. above 80 wt.-%, preferably 90 wt.-%, particularly above 95 wt.-% of magnesia raw material granulate, MgO meal, fine-particle carbon, particularly graphite, if applicable a fine-particle dry silicic acid, particularly in the form of microsilica, and/or, if applicable, a dry, for example powder-form binder, for example containing carbon, for example a synthetic resin binder for refractory products and/or SiC and/or at least one antioxidant and/or at least one additive. The respective rest can be, for example, at least one other refractory coarse-grained material granulate and/or refractory fine-particle material, for example magnesia chromite, magnesium spinels, spinels, chromium oxide, zirconium oxide, silicon nitride, zirconium and/or at least one refractory, fine-particle or meal-form admixture such as magnesia chromite, magnesium spinels, spinels, chromium oxide, zirconium oxide, silicon nitride, zirconium. Furthermore, it is practical if at least one known additive for refractory batches, such as a liquefier and/or binding regulator is/are present.

For example, within the scope of the invention, pressed by means of pressing or non-pressed molded bodies are produced from a batch mixture as indicated above, containing water and/or containing binder, and the molded bodies are brought to residual moisture values preferably between 0.1 and 2 wt.-% by means of drying and/or tempering, for example, or, according to a further embodiment, the molded bodies are additionally fired ceramically in a ceramic kiln, at temperatures between preferably 400 and 1400, particularly between 600 and 1200° C., preferably in a reducing atmosphere, for a period preferably between 1 and 24, particularly between 4 and 12 hours. In this regard, the firing conditions are selected, according to the invention, in such a manner that the components magnesia raw material, MgO meal, and reducing reagent, for example graphite, do not react with one another during firing, if possible, or do so only to a slight degree, so that these components are available in the structure in situ, in the smelting unit, for example in the converter, during attack of a melt and/or slag, in order to guarantee refractoriness according to the invention, particularly to guarantee the anti-wetting effect for the non-ferrous metal melt and the chemical-physical stiffening effect against slag melt and the reducing effect of the reducing reagent.

Using the non-fired and fired molded bodies according to the invention, it is possible to produce linings of non-ferrous metal smelting converters that are superior to previous linings with regard to infiltration resistance and corrosion resistance to non-ferrous metal melts and liquid slags of non-ferrous metal smelting. In particular, the superiority of the refractory products according to the invention is shown in copper smelting converters, for example in a Pierce-Smith converter (PS converter).

The non-fired, pressed, dried molded bodies have the following properties, for example:

Raw density: 2.65 to 3.15 kg/m³,

Cold pressure strength: 40 to 100, particularly 60 to 85 MPa.

The fired, molded bodies according to the invention have the following properties, for example:

Raw density: 2.55 to 3.15 kg/m³,

Cold pressure strength: 30 to 80, particularly 40 to 70 MPa.

The prefabricated parts according to the invention, that is molded parts, particularly molded and pressed bricks, have the following properties, for example:

Raw density: 2.55 to 3.15 kg/m³,

Cold pressure strength: 30 to 180, particularly 50 to 150 MPa.

Although the products according to the invention are especially suitable for use in PS converters for copper production, they can also be used, with advantages as compared with the usual refractory products, in other applications in which fayalitic slags and inviscid non-ferrous metal melts occur, as is the case in practically the entire non-ferrous metal industry, with the advantages as described.

The concept according to the invention is based on the fact that based on magnesia coarse grain as the supporting grain and a relatively high proportion of MgO fine grain or meal grain, equilibrium in the brick, between the reagents coming from the brick and the slag, only occurs at smelting process temperatures above 1000° C., for example between 1200 and 1350° C. At these temperatures, graphite is still effective against the molten media that have already been described, with regard to anti-wetting effect. MgO reacts with SiO₂ to produce further forsterite, with the pore volume of the structure being reduced. According to the invention, MgO is selected in stoichiometric excess relative to SiO₂ that is available for a reaction, in order to prevent the formation of enstatite, which is not refractory. This reaction in situ during the smelting process seals the brick directly on the fire side, to a great extent, and prevents penetration by the very inviscid metal melt, for example copper melt. Furthermore, in contact With the omnipresent fayalite slag melt (melting temperature 1210° C.) the MgO reacts together with the forsterite (melting temperature 1890° C.) to form olivine mixed crystals. The liquidus temperature of the mixed crystal melt thereby increases, i.e. the reaction product slag-product structure freezes up, i.e. leads to stiffening of the reaction product melt, and the corrosion reaction or infiltration is correspondingly stopped or at least greatly reduced.

According to the invention, one therefore allows pressed molded bodies containing at least magnesia raw material, MgO and, if applicable, fine-particle silicic acid, as well as reducing reagent, for example graphite, which bodies have a water content between 1 and 5, particularly between 1.5 and 3 wt.-%, to harden, with MSH phases forming, if applicable, which bring about the hardening. The hardening time is temperature-dependent. It is practical if the pressed molded bodies are allowed to harden for 6 to 120, particularly 24 to 96 hours, and to dry in the temperature range between 50 and 200, particularly between 100 and 150° C., to residual moisture values between 0.1 and 4.5, particularly between 0.1 and 2.5 wt.-% water content, in a suitable drying unit. In this regard, cold pressure strength values between 40 and 100, particularly between 60 and 85 MPa are achieved.

The non-pressed fresh masses, cast into molds and, if necessary, vibrated, which can be produced according to the invention for monolithic prefabricated parts composed of the above-mentioned components have water contents between 4 and 10, particularly between 4 and 6 wt.-%. They are introduced into molds and vibrated, if necessary. They are allowed to harden in air between 15 and 35° C., for example, and to dry in the temperature range indicated above for pressed molded bodies, down to residual moisture values as in the case of the pressed molded bodies. In this regard, cold pressure strength values between 30 and 180, particularly between 50 and 150 MPa are achieved.

According to a further embodiment of the invention, a known binder for refractory products, which contains water, is used in place of water or preferably in combination with it, for example for the MSH phase formation, from the following group of lignin sulfonate, magnesium sulfate, ethyl silicate, and molasses or other types of sugar, in an amount calculated for the dry substance of a batch from 2 to 5 wt.-%, for example, for pressed products and from 4 to 10 wt.-%, for example, for prefabricated parts and casting masses. In this regard, the water proportion of these binders contributes to the MSH phase formation described above.

Furthermore, within the scope of an embodiment of the invention, a known binder for refractory products from the group of pitch and/or tar and, in particular, of the known synthetic resins such as phenolic formaldehyde resins is used in batches according to the invention or products according to the invention, in amounts of 2 to 5 wt.-%, for example, with reference to the dry substance, in each instance.

The products according to the invention are particularly suitable for use in PS converters for copper production, but can also be used in other applications with the same advantages in comparison with usual refractory products, in which applications fayalitic slags and inviscid non-ferrous metal melts occur, as is the case in non-ferrous metal smelting processes, with the advantages as described.

Bricks produced from the batches do not necessarily have to be fired, but rather it is generally sufficient if they are dried, if applicable and/or tempered, so that they can be handled and can be used for lining masonry. 

1. Refractory product in the form of a dry, mineral batch of refractory mineral materials, composed, in terms of materials, in such a manner that refractory products for fire-side lining of industrial non-ferrous metal smelting furnaces that are resistant to fayalite slags, sulfidic melts (mattes), sulfates, and non-ferrous metal melts, over the long term, can be produced from them, and having: at least one coarse-grained magnesia raw material as the main component, magnesia meal (MgO meal), at least one refractory reagent that acts to reduce non-ferrous metal oxide melts and/or non-ferrous metal iron oxide melts during the smelting process (in situ) and to convert them to non-ferrous metal melts.
 2. Product according to claim 1, wherein the reagent is fine-grained carbon, particularly graphite and/or carbon black and/or anthracite and/or coke, but preferably graphite.
 3. Product according to claim 1, comprising the following dry substance compositions: 30 to 74, particularly 40 to 60 wt.-% coarse-grained magnesia, particularly with more than 90, particularly more than 95 wt.-% MgO, 25 to 50, particularly 35 to 45 wt.-% magnesia meal, particularly with >90, particularly >95 wt.-% MgO, 1 to 20, particularly 5 to 15 wt.-% reagent.
 4. Product according to claim 1, wherein in addition, the batch contains SiC, preferably in amounts up to 15, particularly up to 10 wt.-%.
 5. Product according to claim 1, wherein in addition, the batch contains at least one fine-particle silicic acid that reacts with the MgO meal, when water is added to the batch, to form magnesium silicate hydrate phases, preferably in amounts up to 8, particularly up to 5 wt.-%.
 6. Product according to claim 1, wherein in addition, the batch contains at least one known binder for refractory products, in dry, fine-particle form, preferably in amounts up to 10, particularly 0.1 to 6 wt.-%.
 7. Batch according to claim 6, wherein the binder is a binder that contains carbon, particularly tar and/or pitch, but preferably a synthetic resin binder.
 8. Product in the form of a molded refractory brick, produced from a refractory batch according to claim 1, by means of mixing the batch with water and/or a liquid binder for refractory products, to form a moldable fresh mass, and pressing the fresh mass and preferably drying and/or tempering the brick, wherein the brick has at least the components in the brick structure.
 9. Product according to claim 8, having at least one binder phase that has hardened from the binder for refractory products and firmly connects the batch grains.
 10. Product according to claim 8, wherein the brick is ceramically fired and has sintering bridges between batch grains.
 11. Product according to claim 8, wherein the binder phase has a coke structure.
 12. Product according to claim 8, wherein the binder phase contains magnesium silicate hydrate.
 13. Refractory product in the form of fire-side refractory masonry in an industrial non-ferrous metal smelting furnace, particularly in a copper smelting furnace, built from refractory bricks according to claim
 8. 14. Refractory product in the form of a monolithic fire-side refractory lining of an industrial non-ferrous metal smelting furnace, particularly a copper smelting furnace, produced by means of mixing a batch according to claim 1 with water and/or a liquid binder for refractory products, to form a fresh mass, lining the inner wall of the industrial non-ferrous metal smelting furnace with the fresh mass on the fire side, and preferably drying and/or tempering the lining. 